Structure and method for transverse field enhancement

ABSTRACT

Structures and methods for making a magnetic structure are discussed. Various embodiments increase a magnetic field to unambiguously select a magnetic memory cell structure. One method includes folding a current line into two portions around a magnetic memory cell structure. Each portion contributes its magnetic flux to increase the magnetic field to unambiguously select the magnetic memory cell structure. Another method increases the flux density by reducing a cross-sectional area of a portion of the current line, wherein the portion of the current line is adjacent to the to the magnetic memory cell structure.

RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 10/687,463, filed Oct. 15, 2003, now U.S. Pat. No. 6,807,093, which is a divisional of U.S. patent application Ser. No. 10/251,340, filed Sep. 19, 2002, issued Jan. 27, 2004 as U.S. Pat. No. 6,683,338, which is a divisional of U.S. patent application Ser. No. 09/916,563, filed Jul. 26, 2001, issued Jun. 10, 2003 as U.S. Pat. No. 6,576,480.

TECHNICAL FIELD

This invention relates generally to magnetic structures. More particularly, it pertains to enhancing memory devices using magnetic material so that a desired memory cell is selected while other memory cells are unselected.

BACKGROUND OF THE INVENTION

A memory device is a device where information typically in the form of binary digits can be stored and retrieved. Such a device includes dynamic random access memory (DRAM), static random access memory (SRAM), and flash memory. Despite being slower, DRAMs are more commonly used than other memory types because they can be fabricated in high density to store a large amount of information. SRAMs are usually reserved for use in caches because they can operate at high speed. Unlike both DRAMs and SRAMs, which retain information as long as there is applied power, flash memory is a type of nonvolatile memory, which will keep information even if power is no longer applied. Flash memory is typically not used as main memory, however, because its block-oriented architecture prevents memory access in single-byte increments.

Another memory type has emerged that can be fabricated in high density, operated at high speed, and retain information even after power is no longer applied. This memory type is magnetic random access memory (MRAM). FIG. 1A is a block diagram showing a portion of an MRAM array 100 according to the prior art. The MRAM array 100 includes a number of memory cells, such as memory cells 106 _(1,1) to 106 _(3,4), which are arranged in a number of rows (word lines), 104 ₁ to 104 ₃, and a number of columns (bit lines), 102 ₁ to 102 ₄. Each of these memory cells 106 _(1,1) to 106 _(3,4) stores information magnetically instead of electronically as in DRAMs, SRAMs, and flash memory. As an example, to select the memory cell 106 _(2,3) for reading and writing, a row current I_(row) is issued over the row 104 ₂ and a column current (I_(col)) is issued over the column 102 ₃.

FIG. 1B is a partial cross-sectional isometric view of the portion of the MRAM array 100 according to the prior art. Each memory cell is sandwiched between a portion of a row and a portion of a column. Rows and columns are formed from strips of conductive material.

Following the example above, when the row current I_(row) is present in the row 104 ₂, the magnetic field H_(y) that is generated by this current partially selects memory cells 106 _(2,1) to 106 _(2,4). When the column current I_(col) is present in the row 102 ₃, the magnetic field H_(x) that is generated by this current partially selects memory cells 106 _(1,3) to 106 _(3,3). Because memory cell 106 _(2,3) is exposed to both magnetic fields (H_(x) and H_(y)), it is fully selected for reading or writing information.

FIG. 1C is an exploded isometric view of the memory cell 106 _(2,3) and a portion of the row 104 ₂ and the column 102 ₃ according to the prior art. The row current I_(row) creates the magnetic field H_(y) that comprises a magnetic flux line 108 and the column current I_(col) creates the magnetic field H_(x) that comprises a magnetic flux line 110. These magnetic flux lines, 108 and 110, change the dipolar orientation of the memory cell (north or south) 106 _(2,3). In this way, by taking advantage of the dipolar nature of a magnetic material that comprises the memory cell 106 _(2,3), a bit of information can be represented as a 0 or a 1.

FIG. 1D is a graph showing the ferromagnetic nature of the memory cell 106 _(2,3) according to the prior art. The graph shows a hysteresis loop 112, which shows the relationship of induction B as a function of magnetic field strength, H. With a sufficient coercive field x, applied to the memory cell 106 _(2,3), the magnitude of the induction B rises until it levels off at a saturation induction, B_(s0). The coercive field H_(c) is a combination of the magnetic fields H_(x) and H_(y). As the coercive field H_(c) is removed by withdrawing power to the memory cell 106 _(2,3), much of the induction B is retained by dropping its magnitude to a remanent induction B_(r0). This ability to retain the induction B even after power is no longer applied allows each memory cell of the MRAM array 100 to be nonvolatile. The induction B can be moved to another saturation induction, B_(s1), by the application of the coercive field H_(c). When power is again withdrawn, the magnitude of the induction B drops slightly to settle at a remanent reduction B_(r1). A bit of information can be magnetically represented as a 0 or a 1 by forcing the induction B to settle at the remanent induction B_(r0) or B_(r1).

FIG. 1E is a graph showing the ferromagnetic nature of the memory cell 106 _(2,3) as a relationship between resistance R and coercive field H_(c) according to the prior art. This relationship is shown as a hysteresis loop 114, which illustrates that the memory cell 106 _(2,3) exhibits a high resistance R_(H) at one magnetized orientation (remanent induction B_(r0)) and a low resistance R_(L) at another magnetized orientation (remanent induction B_(r1)). As a practical matter, it is less complicated to measure resistance to determine whether a 0 or a 1 is being stored by the memory cell 106 _(2,3) than to measure the induction B as shown in FIG. 1D.

FIG. 1F is a graph showing the coercive field H_(c) that defines the relationship between the magnetic field H_(y), which is formed from the row current I_(row), and the magnetic field H_(x), which is formed from the column current I_(col) according to the prior art. The shaded area 116 ₀, which is underneath the curve of the coercive field H_(c), defines a region where the memory cell 106 _(2,3) is partially selected but is not sufficiently selected for reading and writing information despite the application of one or both the magnetic fields H_(x) and H_(y). The area 118 ₀, which is above the curve of the coercive field H_(c), defines a region where the memory cell 106 _(2,3) is fully selected because both the magnetic fields H_(x) and H_(y) are of a sufficient magnitude. The dashed line 120 illustrates an application of both the magnetic fields H_(x) and H_(y) at the same magnitude to select the memory cell 106, and to unselect (or partially select) memory cell 106 _(2,3) when only one of the magnetic fields H_(x) and H_(y) is applied.

FIG. 1G is a graph showing a full-select probability distribution 118 ₁, which represents a range of H_(x) where the memory cell is fully selected, and a partial-select probability distribution 116 ₁, which represents another range of H_(x) where the memory cell is partially selected, according to one embodiment of the present invention. The probability distribution 118 ₁ reflects the application of both the magnetic fields H_(x) and H_(y) at the same magnitude to fully select the memory cell 106 _(2,3). The probability distribution 116 ₁ reflects the application of only the magnetic field H_(x) but not H_(y) to unselect (or partially select) the memory cell 106 _(2,3). As shown, a portion of the area under the probability distribution 118 ₁ overlaps with a portion of the area under the probability distribution 116 ₁. This overlapped area indicates that an ambiguity exists in the process of selecting the memory cell 106 _(2,3). For example, in certain circumstances, the memory cell 106 _(2,3) may be fully selected even though only the magnetic field H_(x) is applied. This accidental selection of a memory cell may compromise the integrity of the data stored by the memory cells.

Without a solution to unambiguously select a magnetic memory cell for reading and writing information, consumers may question the reliability of this type of memory device, which may lead to its eventual lack of acceptance in the marketplace. Thus, there is a need for structures and methods to increase the reliability of magnetic memory devices.

SUMMARY OF THE INVENTION

An illustrative aspect of the present invention includes various methods for increasing a magnetic field to unambiguously select a magnetic memory cell structure. One method includes folding a current line into two portions around a magnetic memory cell structure. Each portion contributes its magnetic flux to increase the magnetic field to unambiguously select the magnetic memory cell structure. Another method increases the flux density by reducing a cross-sectional area of a portion of the current line, wherein the portion of the current line is adjacent to the magnetic memory cell structure.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a block diagram showing a portion of an MRAM array according to the prior art. FIG. 1B is a partial cross-sectional isometric view of the portion of the MRAM array according to the prior art. FIG. 1C is an exploded isometric view of a magnetic memory cell according to the prior art. FIG. 1D is a graph showing the ferromagnetic nature of a memory cell according to the prior art. FIG. 1E is a graph showing the ferromagnetic nature of a memory cell as a relationship between resistance R and coercive field H_(c) according to the prior art. FIG. 1F is a graph showing the coercive field H_(c) that defines the relationship between the magnetic field H_(y), which is formed from the row current I_(row), and the magnetic field H_(x), which is formed from the column current I_(col) according to the prior art FIG. 1G is a graph showing a full-select probability distribution, which represents a range of values for the magnetic field H_(x) where the memory cell is fully selected, and a partial-select probability distribution, which 7 represents another range of values for the magnetic field H_(x) where the memory cell is partially selected, according to one embodiment of the present invention.

FIG. 2A is a graph showing the coercive field H_(c) that defines the relationship between the magnetic field H_(y), which is formed from the row current I_(row), and the magnetic field H_(x), which is formed from the column current L_(col) according to one embodiment of the present invention. FIG. 2B is a graph showing a full-select probability distribution, which represents a range of H_(x) where the memory cell is fully selected, and a partial-select probability distribution, which represents another range of H_(x) where the memory cell is partially selected, according to one embodiment of the present invention.

FIG. 3A is a cross-sectional view of a magnetic structure according to one embodiment of the present invention. FIGS. 3B-3G are cross-sectional views of a magnetic structure during processing according to one embodiment of the present invention.

FIG. 4A is a cross-sectional view of a magnetic structure according to one embodiment of the present invention. FIGS. 4B-4F are cross-sectional views of a magnetic structure during processing according to one embodiment of the present invention.

FIG. 5A is a cross-sectional plan view of a magnetic structure according to one embodiment of the present invention. FIG. 5B is a cross-sectional plan view of a magnetic structure according to another embodiment of the present invention. FIGS. 5C-5G are crop sectional plan views of a magnetic structure during processing according to one embodiment of the present invention.

FIG. 6 is a block diagram of a computer system according to one embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

In the following detailed description of various embodiments of the invention, reference is made to the accompanying drawings, which form a part hereof, and in which are shown, by way of illustration, specific embodiments in which the invention may be practiced. In the drawings, like numerals describe substantially similar components throughout the several views. The lateral sizes and thicknesses of the various layers are not drawn to scale and these various layers or layer portions are arbitrarily enlarged or reduced to improve drawing legibility. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. Other embodiments may be utilized and structural, logical, electrical, and other changes may be made without departing from the spirit or scope of the present invention. The following detailed description is, therefore, not to be taken in a limiting sense.

FIG. 2A is a graph showing the coercive field H_(c) that defines the relationship between the magnetic field H_(y), which is formed from the row current I_(row), and the magnetic field H_(x), which is formed from the column current I_(col), according to one embodiment of the present invention. FIG. 2B is a graph showing a full-select probability distribution 122 ₁, which represents a range of H_(x) where the memory cell is fully selected, and a partial-select probability distribution 116 ₁, which represents another range of H_(x) where the memory cell is partially selected, according to one embodiment of the present invention. The area 122 ₀, which is above the curve of the coercive field H_(c), defines a region where the memory cell is fully selected because both the magnetic fields H_(x) and H_(y) are of a sufficient magnitude.

Unlike the prior art, the full-select probability distribution 122 ₁ is separated from the partial-select probability distribution 116 ₁ so that any memory cell can be unambiguously selected. Various embodiments of the present invention separate the probability distributions 122 ₁ from 116 ₁ by increasing the magnetic field H_(y) to a level H_(yH) while lowering the magnetic field H_(x) to a level H_(xL). Recall that the magnetic field H_(y) is generated from the row current I_(row). Thus, one technique to increase the magnetic field H_(y) is to increase the row current I_(row). However, depending on the material that is used to form a word line in which the row current I_(row) flows, an increased row current I_(row) may cause electromigration. Other problems associated with an increased row current L include increased power dissipation and heat.

The embodiments of the present invention avoid the need to increase the row current I_(row) yet still manage to increase the magnetic field H_(y) by various methods. These methods are illustrated below using magnetic structures. One such magnetic structure is shown by FIG. 3A, which illustrate one method to increase the magnetic field H_(y). Another method is shown by magnetic structures illustrated in FIGS. 4A and 5A.

FIG. 3A is a cross-sectional view of a magnetic structure 300 according to one embodiment of the present invention, which presents one method to increase the magnetic field H_(y). The steps to fabricate the magnetic structure 300 are illustrated in FIGS. 3B-3G, which are discussed hereinbelow. The magnetic structure 300 includes a substrate 302 in which a conductive line 304 is formed to conduct a row current I_(row). A number of memory cells, such as 310 ₁, 310 ₂, and 310 ₃, are fabricated on the conductive line 304. For the sake of brevity, these memory cells, 310 ₁, 310 ₂, and 310 ₃, may include multiple layer memory cells but are not shown here so as to focus on the embodiments of the present invention. These memory cells, 310 ₁, 310 ₂, and 310 ₃, are electrically isolated from one another and structurally supported by a layer of nonconductive material 308. Another conductive line 312, which is to further conduct the row current I_(row), is fabricated on the nonconductive layer 308 and the memory cells 310 ₁, 310 ₂, and 310 ₃. The conductive line 304 and the conductive line 312 are electrically coupled together through a via 306 in which a conductive material is filled.

The magnetic structure 300 increases the magnetic field H_(y) by increasing the magnetic flux lines that couple the memory cells 310 ₁, 310 ₂, and 310 ₃. To illustrate this, suppose the row current I_(row) flows in the conductive line 304 from left to right. Using the right-hand rule, a set of magnetic flux lines that are generated by the row current I_(row) can be visualized as a number of rings, which encircle the conductive line 304 by entering into a page on which FIG. 3A is drawn at a certain distance below the conductive line 304, and exit out of the page at a certain distance above the conductive line 304 to couple the memory cells 310 ₁, 310 ₂, and 310 ₃.

The row current I_(row) flows from the conductive line 304 to enter the via 306, and from the via 306, the row current I_(row) flows in the conductive line 312 from the right to the left. Again using the right-hand rule, another set of magnetic flux lines encircles the conductive line 312 by entering into the page on which FIG. 3A is drawn at a certain distance above the conductive line 312, and exits out of the page at a certain distance below the conductive line 312 to couple the memory cells 310 ₁, 310 ₂, and 310 ₃. The two sets of magnetic flux lines generated from the conductive lines 304 and 312 help to increase the magnetic field H_(y) over the set of magnetic flux lines generated from the conductive line 304 alone.

In alternative embodiments of the present invention, the magnetic field coupling the magnetic memory cell is increased by increasing the induction B. The magnitude of the induction B is the flux density, which is in turn proportional to the current density. Recall that the current density is defined as the magnitude of current per unit area or (I/A), wherein I is the magnitude of current and A is the cross-sectional area of the conductor in which the current is conducting. Thus, increasing the current density consequently increases the induction B. Based on the relationship between current and cross-sectional area of the conductor, the current density can be increased by increasing the magnitude of the current or decreasing the cross-sectional area of the conductor, or both. Some embodiments of the present invention increase the induction B by decreasing the cross-sectional area of the conductor in the proximity of the magnetic memory cell.

A cross-sectional view of one such magnetic structure is illustrated in FIG. 4A as a magnetic structure 400. FIGS. 4B-4F, which are discussed below, provide cross-sectional views of the magnetic structure 400 at various steps during its fabrication. Although only one memory cell 310 is illustrated in FIG. 4A, it will be appreciated that the present embodiment may be applied to an entire array of memory cells. As shown in FIG. 4A, the memory cell 310 is formed on a conductive line 406 that can be visualized as extending into and out of the page on which FIG. 4A is drawn. The conductive line 406 is itself formed in a substrate 302, and is used to conduct a column current I_(col). A nonconductive layer 308 electrically isolates the memory cell 310 from adjacent memory cells (not shown), and provides a structure on which subsequent layers are formed. Another conductive line 404 is formed on the nonconductive layer 308 and over a portion of the memory cell 310 that remains exposed through the non-conductive layer 308. The conductive line 404 is used to provide a row current I_(row). As will be described in more detail below, by forming the conductive layer 404 such that the resulting cross-sectional area of the portion passing over the magnetic cell is less than the cross-sectional area of the remaining portions of the conductive layer 404, a higher flux density, and consequently, a higher magnetic field H_(y), is created in the region proximate to the memory cell 310.

Another cross-sectional view of a magnetic structure 500 in which the induction B is increased by decreasing the cross-sectional area of the conductor is shown in FIG. 5A. FIGS. 5C-5G show a fabrication process at various steps that produces the magnetic structure 500. Two memory cells, 310 ₁ and 310 ₂, are shown but it should be appreciated that the present embodiment may be applied to an entire array of memory cells. FIG. 5B shows another cross-sectional view of another magnetic structure 501 that increases the induction B in a similar way as shown in FIG. 5A except that the two memory cells, 310 ₁ and 310 ₂, instead of being fabricated above are fabricated under the conductive line 504.

The conductive line 504 is formed in a substrate 302 to conduct a row current I_(row). Because the conductive line 504 is fabricated under the two memory cells 310 ₁ and 310 ₂, for clarity purposes the outline of the conductive line 504 is shown as a dashed line underneath the memory cells 310 ₁ and 310 ₂. The conductive line 504 has a width W1 below the memory cells 310 ₁ and 310 ₂ and another width W2 over other sections of the magnetic structure 500 that are not below the memory cells 310 ₁ and 310 ₂. As illustrated in FIG. 5A, the width W1 is less than the width W2. Suppose that the conductive line 504 has a uniform thickness, a cross-sectional area of the conductive line 404 is less than a cross-sectional area taken at other sections. As a result, the difference in the cross-sectional area helps to increase the magnetic field H_(y) by increasing the induction B. As explained hereinabove, increasing the current density consequently increases the induction B, and therefore, increases the magnetic field H_(y).

FIGS. 3B-3G are cross-sectional views of the magnetic structure 300 during processing according to one embodiment of the present invention, which has been earlier summarized in FIG. 3A. These Figures describe an embodiment that increases the magnetic field H_(y) by folding a conductive line around a memory cell to increase the magnetic flux. The discussion in FIGS. 3B-3G illustrates a few of the steps associated with a fabrication process. The entire fabrication process is not discussed so as to focus on the embodiments of the present invention. Other methods of fabrication are also feasible and perhaps equally viable.

FIG. 3B is a cross-sectional view of the magnetic structure 300 during the next sequence of processing according to one embodiment of the present invention. The substrate 302 can be fabricated from any suitable substances and compounds, such as lightly doped n-type or p-type material or a lightly doped epitaxial layer on a heavily doped substrate. Using a damascene process, a trench of about 4000 to 5000 angstroms deep is etched into the substrate 302, which is followed by an electrochemical plating (ECP) process to deposit a highly conductive material, such as copper, and is finished off with a polishing process, such as chemical mechanical polishing (CMP), to level the copper overfill. The result of the damascene process is the conductive line 304 as shown in FIG. 3B. As discussed above in FIG. 3A, this conductive line 304 will be used to conduct a row current (or word line) to select a memory cell.

FIG. 3C is a cross-sectional view of the magnetic structure 300 during the next sequence of processing according to one embodiment of the present invention. A number of memory cells, such as 310 ₁, 310 ₂, and 310 ₃, are fabricated over the conductive line 304. The fabrication process involves a number of photolithographic, etching, and deposition steps to form the memory cells from a number of materials, such as seed materials, anti-ferromagnetic materials, ferromagnetic materials, tunneling materials, and barrier materials. Because the fabrication process of the memory cells does not limit the present invention, such a process will not be explained here in full so as to focus more clearly on the present embodiment.

FIG. 3D is a cross-sectional view of the magnetic structure 300 during the next sequence of processing according to one embodiment of the present invention in which a noncondutive layer 308 is deposited, photolithographed, and etched to electrically isolate and structurally protect the memory cells 310 ₁, 310 ₂, and 310 ₃. The same etching process also forms an opening 311 which will define the via 306 through the nonconductive layer 308. A suitable dielectric material for the nonconductive layer 308 includes silicon dioxide, but any other suitable dielectric materials may be used. A suitable deposition technique includes chemical-vapor deposition and a suitable etching technique includes plasma etching. Other suitable deposition and etching techniques may be used without limiting the embodiments of the present invention.

FIG. 3E is a cross-sectional view of the magnetic structure 300 during the next sequence of processing according to one embodiment of the present invention. A conductive material, such as tungsten, is deposited, photolithographed, and etched to form the via 306 from the opening 311. Any suitable deposition technique, such as sputtering, and any suitable etching technique, such as a wet etch, may be used. Other suitable deposition and etching techniques may be used without limiting the embodiments of the present invention.

FIG. 3F is a cross-sectional view of the magnetic structure 300 during the next sequence of processing according to one embodiment of the present invention in which a noncondutive layer 314 is deposited to electrically isolate and structurally protect the memory cells 310 ₁, 310 ₂, 310 ₃, and the via 306. A suitable dielectric material for the nonconductive layer 314 includes silicon dioxide, but any other suitable dielectric materials may be used. A suitable deposition technique includes chemical-vapor deposition and a suitable etching technique includes plasma etching. Other suitable deposition and etching techniques may be used without limiting the embodiments of the present invention.

FIG. 3G is a cross-sectional view of the magnetic structure 300 during the next sequence of processing according to one embodiment of the present invention. A damascene process is applied to the nonconductive layer 314 to form a trench in the nonconductive layer 314 of about 4000 to 5000 angstroms deep above the memory cells 310 ₁, 310 ₂, and 310 ₃. This etching process is followed by an electrochemical plating process to deposit a highly conductive material, such as copper, and any overfilled conductive material is planarized by a polishing process, such as chemical mechanical polishing. The result of the damascene process is the conductive line 312 as shown in FIG. 3G. As discussed above in FIG. 3A, this conductive line 312 generates additional magnetic flux, which together with the magnetic flux generated by the conductive line 304, help to increase the magnetic field H_(y) without increasing the row current to select a memory cell.

The process of fabricating the embodiment shown in FIG. 4A will now be discussed with respect to FIGS. 4B-4F. The discussion in FIGS. 4B-4F illustrates a few of the steps associated with a fabrication process. The entire fabrication process is not discussed so as to focus on the embodiments of the present invention. Other methods of fabrication are also feasible and perhaps equally viable.

FIG. 4B illustrates the formation of a conductive line 406 in a substrate 302. The substrate 406 can be fabricated from any suitable substances and compounds, such as a lightly doped n-type or p-type material, a lightly doped epitaxial layer, or the like. The conductive line 406 can be formed using a damascene process. That is, a trench having a depth of approximately 4000 to 5000 angstroms is first etched into the substrate 302. The trench is then filled with a conductive material, such as copper, and any overfill is leveled with a polishing process, such as chemical mechanical polishing.

FIG. 4C illustrates the formation of a multi-layer memory cell 310 on the conductive line 406. A barrier layer 408 of tantalum having a thickness of approximately 5 nanometers is first formed to inhibit diffusion of copper atoms from the metal line 406. A layer 410 of nickel ferrite having a thickness of approximately 6 nanometers is formed over the barrier layer 408. Together, the layer 410 and the tantalum layer 408 act as a seed layer to orient the crystalline lattice structure of materials deposited on the nickel ferrite layer 410 to a particular orientation. For example, in one embodiment of the present invention, the seed layer provides a “111” crystalline orientation for subsequent layers.

An anti-ferromagnetic layer 412 of a magnesium ferrite material with a thickness of about 10 nanometers is then formed on the nickel ferrite layer 410. The anti-ferromagnetic layer 412 is fabricated on top of the nickel ferrite layer 410 to act as a pinning layer to pin any magnetic layer which is formed thereon to a certain magnetic orientation and inhibit the particular magnetic orientation from changing. Formed on top of the anti-ferromagnetic 412 is a ferromagnetic layer 414 of a nickel ferrite material. The ferromagnetic layer 414 has a thickness of approximately 6 nanometers, and acts as a pinned layer having a fixed magnetic orientation. A tunneling layer 416, through which electrons are allowed to tunnel so that a current can be measured to derive the resistance of the memory cell 310, is formed from a dialuminum trioxide layer having a thickness of approximately 1.5 nanometers, and deposited on the ferromagnetic layer 414. A sense layer 418 of nickel ferrite with a thickness of about 4 nanometers is formed on the tunneling layer 416 to act as a sense layer having a magnetic orientation that can be changed. Depending on the magnetic orientation of the ferromagnetic layer 418 with respect to the fixed magnetic orientation of the ferromagnetic layer 414, the resistance of the memory cell 310 can be measured, from which a bit of information stored by the memory cell 310 can be determined. The memory cell 310 is completed with another tantalum layer 420 having a thickness of about 5 nanometers which acts as a barrier layer in a manner similar to the tantalum layer 408 previously discussed.

FIG. 4D illustrates the magnetic structure 400 following the formation of a non-conductive layer 308. A non-conductive layer is deposited over the memory cell 310 and then planarized to produce a level surface. As mentioned previously, the non-conductive layer 308 electrically isolates and structurally protects the memory cell 310. A suitable dielectric material for the non-conductive layer 308 includes silicon dioxide. However, other suitable dielectric materials may be used as well. In FIG. 4E, as part of a damascene process, an etching step has been used to form a trench approximately 4000 to 5000 angstroms deep in the non-conductive layer 308 to expose at least a portion of the memory 310. As shown in FIG. 4E, the etching step exposes the barrier layer 420. It is recommended that the etching step should not etch beyond the boundary between the tunneling layer 416 and the ferromagnetic layer 414. As shown in FIG. 4F, following the formation of the trench, a conductive material, such as copper, is deposited into the trench to form a conductive line 404. Any overfill of the conductive material is removed through a planarization process, such as through chemical mechanical polishing.

As a result of the upper surface of the conductive line 404 being relatively level, the depth D1 of the conductive line 404 in the region over the memory cell 310 is less than the depth D2 of the conductive line 404 in the region over the non-conductive layer 308. Consequently, because the width (not shown) of the conductive line 404 is relatively uniform, the cross-sectional area in the region proximate to the memory cell 310 is less than that for elsewhere along the conductive line 404. The region of decreased cross-sectional area provides a region along the conductive line 404 where the current density, and hence the flux density, is increased to provide a region of increased magnetic field strength to be coupled to the memory cell 310.

The process of fabricating the embodiment shown in FIG. 5A is now discussed with respect to FIGS. 5B-5G. The discussion in FIGS. 5B-5G illustrates a few of the steps associated with a fabrication process. The entire fabrication process is not discussed so as to focus on the embodiments of the present invention. Other methods of fabrication are also feasible and perhaps equally viable.

FIG. 5C is a cross-sectional plan view of the magnetic structure 500 showing the formation of a conductive line 504 in a substrate 302. The substrate 302 can be fabricated from any suitable substances and compounds, such as lightly doped n-type or p-type material or a lightly doped epitaxial layer on a heavily doped substrate. Using a damascene process, a trench of about 4000 to 5000 angstroms deep is etched into the substrate 302, which is followed by an electrochemical plating process to deposit a highly conductive material, such as copper, and is finished off with a polishing process, such as chemical mechanical polishing to level the copper overfill. The result of this damascene process is the conductive line 504 having a certain width W2.

FIG. 5D is a cross-sectional plan view of the magnetic structure 500 during the next sequence of processing in which a photolithographic step is applied to form a mask 506 from a resist material. The mask 506 exposes certain portions of the conductive line 504 so that these exposed portions of the conductive line 504 have a width W1, which is less than the width W2. FIG. 5E illustrates the etching of the exposed portions of the conductive line 504. A suitable etching technique includes a dry etch process, such as plasma etching. Should a wet etch process be desired, an organic solvent is recommended be used to etch away the exposed areas of the conductive line 504. FIG. 5F illustrates the stripping of the mask 506 using a solution, such as hydrochloric acid. Once the mask 506 is stripped away, what is remained is a patterned conductive line 504 having two different widths, W1 and W2.

FIG. 5G illustrates the formation of a number of memory cells, such as memory cells 310 ₁ and 310 ₂, on various sections of the conductive line 504 that have the width W1. These memory cells may have multiple layers, such as those discussed in FIG. 4C above. FIG. 5G is similar to FIG. 5A in that the memory cells are fabricated over the conductive line 504. However, an equivalent structure is to fabricate the memory cells first, which is then followed by the fabrication of the conductive line 504, as shown in FIG. 5B.

FIG. 6 is a block diagram of a computer system according to one embodiment of the present invention. Computer system 1000 contains a processor 1110 and a memory system 1102 housed in a computer unit 1105. Computer system 1100 is but one example of an electronic system containing another electronic system, e.g., memory system 1102, as a subcomponent. The memory system 1102 may include a magnetic structure as discussed hereinabove in various embodiments of the present invention. Computer system 1100 optionally contains user interface components. These user interface components include a keyboard 1120, a pointing device 1130, a monitor 1140, a printer 1150, and a bulk storage device 1160. It will be appreciated that other components are often associated with computer system 1100 such as modems, device driver cards, additional storage devices, etc. It will further be appreciated that the processor 1110 and memory system 1102 of computer system 1100 can be incorporated on a single integrated circuit. Such single-package processing units reduce the communication time between the processor and the memory circuit.

Structures and methods have been discussed to address a desire to unambiguously select a particular memory cell for reading and writing information. At least three embodiments of the present invention have been presented. All of these embodiments focus on increasing the magnetic field H_(y), which is generated by the row current (word line). One of the embodiments focuses on increasing the magnetic flux by folding a conductive line, which conducts the row current. The other two embodiments focus on increasing the flux density by decreasing the cross-sectional area of the conductive line. The embodiments of the present invention enhance the manufacturing of magnetic memory devices to produce more reliable products for consumers.

Although the specific embodiments have been illustrated and described herein, it will be appreciated by those of ordinary skill in the art that any arrangement which is calculated to achieve the same purpose may be substituted for the specific embodiments shown. This application is intended to cover any adaptations or variations of the present invention. It is to be understood that the above description is intended to be illustrative, and not restrictive. Combinations of the above embodiments and other embodiments will be apparent to those of skill in the art upon reviewing the above description. The scope of the invention includes any other applications in which the above structures and fabrication methods are used. Accordingly, the scope of the invention should only be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled. 

1. A magnetic structure, comprising: at least one magnetic memory cell structure having multiple layers, the multiple layers including a first ferromagnetic layer, a tunneling layer, and a second ferromagnetic layer; a nonconductive layer surrounding the at least one magnetic memory cell structure so that a portion of the at least one magnetic memory cell structure is exposed therethrough; and a conductive layer which generates a magnetic field to partially select the at least one magnetic memory cell structure when a current passes therethrough, the conductive layer formed over the at least one magnetic memory cell structure and the nonconductive layer, the conductive layer adjoining the exposed portion of the at least one magnetic memory cell structure.
 2. The magnetic structure of claim 1, wherein the conductive layer includes a first depth and a second depth having a magnitude less than the first depth, the second depth corresponding to a portion where the conductive layer adjoins to a top layer of the at least one magnetic memory cell structure.
 3. The magnetic structure of claim 1, wherein the conductive layer is configured to conduct a row current.
 4. The magnetic structure of claim 1, wherein the at least one magnetic memory cell structure comprises a top layer formed over the first ferromagnetic layer, and wherein the top layer comprises a barrier layer.
 5. The magnetic structure of claim 4, wherein the barrier layer comprises tantalum.
 6. A magnetic structure, comprising: a substrate; at least one memory cell structure formed over the substrate; a nonconductive layer surrounding the at least one memory cell structure; and a conductive line adjacent the at least one magnetic memory cell structure, the conductive line generates a magnetic field to partially select the at least one memory cell structure when a current passes therethrough, the conductive line including a first portion having a first width and a second portion having a second width greater than the first width, the first portion adjoining the at least one memory cell structure.
 7. The magnetic structure of claim 6, wherein the conductive line is located below the at least one memory cell structure.
 8. The magnetic structure of claim 6, wherein the conductive line is located above the at least one memory cell structure.
 9. The magnetic structure of claim 6, wherein the conductive line comprises copper.
 10. The magnetic structure of claim 9, wherein the at least one memory cell structure comprises a tantalum barrier layer.
 11. A computer system, comprising: a processor; at least one user interface device; at least one output device; a memory system that comprises a plurality of memory modules, one of the plurality of the memory modules comprising a plurality of memory devices, wherein at least one memory device of the plurality of memory devices comprises a magnetic structure, the magnetic structure comprising: a magnetic memory cell structure having a top and a bottom; and at least one conductive line located relative to the magnetic memory cell structure and structured to unambiguously select the magnetic memory cell structure for reading and writing of information when a current passes therethrough; a plurality of command links coupled to the plurality of memory devices to communicate at least one command signal; and a plurality of data links coupled to the plurality of memory devices to communicate data.
 12. A magnetic memory structure, comprising: at least one memory cell having a ferromagnetic nature which changes between first and second states when subject to application of a magnetic field having a magnitude greater than a threshold value; and a current path, the current path having a first portion providing a first magnetic field and a second portion providing a second magnetic field when a current is conducted through the current path, the sum magnitude of the first and second magnetic fields exceeding the threshold value.
 13. The magnetic memory structure of claim 12, wherein the at least one memory cell comprises a ferromagnetic material having the characteristic that the state of the memory cell is dependent on a previously applied magnetic field.
 14. The magnetic memory structure of claim 13, wherein the at least one memory cell comprises multiple layers, each layer selected from a group consisting of a barrier layer, a seed layer, a pinning layer, a pinned layer, a tunneling layer, and a sense layer.
 15. The magnetic memory structure of claim 14, wherein the barrier layer comprises tantalum.
 16. The magnetic memory structure of claim 14, wherein the seed layer comprises nickel ferrite.
 17. The magnetic memory structure of claim 12, wherein the magnetic memory structure further comprises a first surface and a second surface opposite of the first surface, and the first portion of the current path is located and configured to conduct the current in proximity of the first surface in a first direction and the second portion of the current path is located and configured to conduct the current in proximity of the second surface in a second direction opposite of the first direction.
 18. The magnetic memory structure of claim 17, wherein the first surface is beneath the second surface.
 19. The magnetic memory structure of claim 17, wherein the first surface is perpendicular to the second surface.
 20. A magnetic memory structure, comprising: at least one magnetic memory cell having a ferromagnetic nature to change between first and second states when subject to application of a magnetic field having a magnitude greater than a threshold value; and a current path that creates a magnetic field coupling the at least one magnetic memory cell when a current is conducted therethrough, the current path having a first portion and a second portion, the first portion of the current path adjacent to the magnetic memory cell and having a first cross-sectional area that is less than a second cross-sectional area of the second portion of the current path.
 21. The magnetic memory cell of claim 20, wherein the at least one magnetic memory cell comprises a first surface located beneath a second surface and the first portion of the current path is adjacent to the first surface.
 22. The magnetic memory cell of claim 20, wherein the magnetic memory cell includes a first surface located beneath a second surface, and the first portion of the current path is adjacent to the second surface.
 23. The magnetic memory cell of claim 20, wherein the magnetic memory cell comprises multiple layers, each layer selected from a group consisting of a barrier layer, a seed layer, a pinning layer, a pinned layer, a tunneling layer, and a sense layer.
 24. The magnetic memory cell of claim 20, wherein the first portion of the current path has a first width and the second portion of the current path has a second width, the first width less than the second width.
 25. The magnetic memory cell of claim 20, wherein the first portion of the current path has a first depth and the second portion of the current path has a second depth, the first depth less than the second depth.
 26. A magnetic memory device, comprising: a memory array having a plurality of magnetic memory cells arranged in rows and columns, each of the magnetic memory cells comprising: a memory cell structure having a ferromagnetic nature to change between first and second states when subject to application of a magnetic field having a magnitude greater than a threshold value; and a current path to provide a magnetic field that couples the memory cell structure when a current is conducted therethrough, the current path having a first portion providing a first magnetic field and a second portion providing a second magnetic field when a current is conducted through the current path, the sum magnitude of the first and second magnetic fields exceeding the threshold value.
 27. A magnetic memory device, comprising: a memory array having a plurality of magnetic memory cells arranged in rows and columns, each of the magnetic memory cells comprising: a memory cell structure having a ferromagnetic nature to change between first and second states when subject to application of a magnetic field having a magnitude greater than a threshold value; and a current path that creates a magnetic field coupling the memory cell structure when a current is conducted therethrough, the current path having a first portion and a second portion, the first portion of the current path adjacent to the magnetic memory cell structure and having a first cross-sectional area that is less than a second cross-sectional area of the second portion of the current path. 